Stabilization of glutamate dehydrogenase in an aqueous solution

ABSTRACT

A process for stabilizing glutamate dehydrogenase (GDH) from a bacterium of the Clostridium genus, in an aqueous solution, in order to maintain the antigenic properties thereof, includes the step of mixing the glutamate dehydrogenase and a stabilizing composition which is a carboxylic acid having a carbon-based chain of at least 3 carbon atoms and comprising at least 2 —COOH groups, or a salt thereof. GDH compositions thus stabilized and a method of detecting the presence of bacteria of the Clostridium genus are also disclosed.

The present invention relates to the field of the in vitro detection of bacterial proteins in biological samples that may contain these proteins. In particular, the invention relates to the stabilization of glutamate dehydrogenase from a bacterium of the Clostridium genus so that this protein retains the antigenic properties thereof when it is in an aqueous solution.

Bacteria of the Clostridium genus are Gram-positive, sporulated, anaerobic bacteria which are incapable of reducing sulfates to sulfites. Some species are very pathogenic, such as Clostridium difficile, Clostridium botulinum and Clostridium perfringens, these being the most well-known.

The Clostridium difficile bacterium is the main agent responsible for diarrhea following the administration of antibiotics. It is formidable because of its very high contagion potential. Although approximately 5% of the population are asymptomatic carriers of the bacterium, its pathological manifestations are closely linked to time spent in hospital. This bacterium develops in an intestinal flora weakened by treatment with antibiotics and can secrete two toxins, A and B. Only the toxin-producing strains are pathogenic. Toxin A, an enterotoxin, causes modification of intestinal epithelium permeability; toxin B, a cytotoxin, directly attacks the cells of the epithelium. The combined effect of the two toxins is a decrease in intestinal transit time and in intestinal absorption, thereby resulting in diarrhea. More rarely, the Clostridium difficile bacterium can cause a severe inflammation of the colon (pseudomembraneus colitis).

The Clostridium botulinum bacterium, for its part, is responsible for botulism. It produces spores which represent the resistance form of the bacterium. These spores can withstand weak heat treatments, such as pasteurization, which can pose food safety problems, and can then give a metabolically active bacterial cell capable of multiplying. This bacterium secretes one of the most powerful toxins of the living world, the botulinum toxin. Active by ingestion, this toxin then diffuses in the organism and acts by blocking neuromuscular transmission: it inhibits the motor neurons of muscle contraction. This infection can cause death by paralysis of the respiratory muscles if no treatment is put in place.

The Clostridium perfringens bacterium is a bacterium which develops in wombs, sometimes very deeply. This bacterium will produce necrotoxins, thus causing necrotizing enteritis. The most common major toxin is the alpha toxin, essentially produced by Clostridium perfringens type A. This toxin is involved in a very large number of cases of gangrene in humans and animals. Alone or in combination with other toxins, it also causes abrupt mortalities in pigs and ruminants.

The detection of the presence of these bacteria and of the secretion of their toxin is therefore a major public health problem which requires laboratories to have detection tests that are reliable, both in terms of sensitivity/specificity, and in terms of reproducibility of the results obtained with these tests. To do this, laboratories in particular need tests which include reagents that do not degrade over time and therefore remain stable.

The detection of the presence of bacteria in samples can be carried out by various techniques, such as the use of culture media or the technique of immunoassays, which are widely known to those skilled in the art. The immunoassay technique is a technique consisting broadly in detecting the presence of proteins using binding partners of these proteins. In the context of the detection of bacteria of the Clostridium genus, one of the detectable proteins, representative of the presence of this bacterium, is glutamate dehydrogenase (GDH). Other detectable proteins are the toxins secreted when the bacteria are toxigenic. The detection or quantification of GDH by immunoassay is a technique which makes it possible to have a greater diagnostic sensitivity than the detection or quantification of toxins by immunoassay. It is used as a screening means on populations at risk. In the event of a positive result, a search for toxins is then recommended since this technique has, for its part, a greater specificity.

Several diagnostic companies propose kits for detecting GDH in Clostridium difficile. Mention may, for example, be made of the VIDAS® GDH kit from the applicant.

In addition to the binding partners, the immunoassay technique also requires the use of reagents for calibrating and/or controlling the test. Thus, in the context of a GDH immunoassay, such reagents comprise GDH as such, which must retain its antigenic properties for as long as required from the viewpoint of the shelf life of the diagnostic kit in which it is contained.

The properties of a protein can be disrupted by any structural modification, both from a chemical point of view and from a physical point of view. The chemical modifications of a protein are based on changes at the level of the covalent bonds, due for example to oxidation, hydrolysis, etc., reactions, while the physical modifications, also called denaturation, cause a disorganization of the tertiary structure or three-dimensional conformation of the protein, without breaking of the covalent bonds. Protein denaturation can be induced by many chemical or physical factors, such as, inter alia, temperature, pH modification or a chemical agent. The consequence of such modifications is a disruption of the protein's actual activity. Thus, in the context of an enzyme such as GDH, such modifications can modify its enzymatic activity, something which the various authors have tried to overcome.

Thus, for example, the authors of patent application WO 2007/003936 have described the stabilization of the enzymatic activity of various proteins using one or more stabilizing compounds having the following characteristics:

-   -   They have ionizable groups capable of proton exchange with the         protein to be stabilized and with the ionized products of the         aqueous solution,     -   The ionizable groups include first groups which are positively         charged when they are protonated and uncharged when they are         deprotonated, and second groups which are uncharged when they         are protonated and negatively charged when they are         deprotonated, and     -   The pH of the composition is maintained in a range of +/−0.5 pH         units of the pH at which the composition has its maximum         stability relative to the pH.         This document indicates that the enzymatic activity of bovine         GDH is preserved by adding lysine as stabilizing compound,         whereas the addition of citrate does not allow GDH to retain         this enzymatic activity.

Garcia-Galan C. et al., 2013, have for their pan indicated that Escherichia coli GDH can be stabilized so that it maintains its enzymatic activity by coating the surface of the GDH with polyethyleneimine in the presence of lithium⁺.

However, no author has shown an interest in searching for how to stabilize GDH so that it retains its antigenic properties, although this is a problem encountered when this protein is used in an aqueous solution, in particular in a very dilute manner, for example at a concentration of about a few ng/ml.

Indeed, GDH is usually stored in lyophilized form since it is known that it does not retain its antigenic properties when it is placed in an aqueous solution. Thus, when GDH must be placed in an aqueous solution, for example in the context of a GDH immunoassay, the laboratory assistant takes up the lyophilized GDH in an aqueous solvent, and prepares aliquots that must then be frozen at −20° C. The expiration date of the aqueous solution is then quite short, on average two months stored between 2 and 8° C. Furthermore, taking up the GDH in an aqueous buffer has the drawbacks of leading not only to additional manipulations, but also to additional risks of error when it is taken up. Finally, this also requires the presence of a freezer.

The applicant has found, against all expectations, that it is possible to stabilize GDH in an aqueous solution so that its three-dimensional structure is at least partly preserved such that it keeps its antigenic properties. Such a stabilization is carried out by addition, as stabilizing compound, of a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or of a salt thereof. By virtue of the addition of this compound, the aqueous solution comprising the GDH can be stored between 2 and 8° C., for many months.

Thus, a first subject of the invention relates to a process for stabilizing glutamate dehydrogenase from a bacterium of the Clostridium genus in order to maintain the antigenic activity thereof, comprising the step of mixing, with said glutamate dehydrogenase in an aqueous solution, a stabilizing compound which is a carboxylic acid having a carbon-based chain of at least three carbon atoms and at least two —COOH groups, or a salt thereof.

Another subject of the invention relates to the stabilized aqueous compositions thus obtained, and also to the diagnostic kits comprising these compositions.

Yet another subject of the invention relates to the use of the compositions for establishing standard ranges in the context of a GDH immunological assay.

Yet another subject of the invention relates to the use of the compositions as a calibrator and/or control in the context of as GDH immunological assay.

Finally, a last subject of the invention relates to the processes for detecting the presence of a bacterium of the Clostridium genus using a composition of the invention, the bacterium being, where appropriate, toxigenic.

The applicant has therefore shown, against all expectations, that the use of specific compounds makes it possible to stabilize GDH from bacteria of the Clostridium genus in order to maintain the antigenic properties thereof when the GDH is in an aqueous solution, in particular in concentrations of about to few ng/ml, for example from 0.75 to 10 ng/ml, from 2 to 10 ng/ml or else from 3 to 6 ng/ml, which is particularly important in the context of tests for detecting these bacteria by immunoassay.

The expression “maintaining the antigenic properties of the GDH” is intended to mean that the GDH retains its property of binding to the binding partners used in the context of the immunoassay since its structure is preserved, at least in terms of the antigenic determinant involved in the binding of the binding partner.

Of course, the prefix “immuno” in the term “immunoassay”, for example, is not to be considered in the present application as strictly indicating that the binding partner is necessarily a partner of immunological origin, such as an antibody or an antibody fragment. Indeed, as is well known to those skilled in the art, this term is more widely used to denote tests and processes in which the binding partner is not a partner of immunological origin/nature, but consists, for example, of a receptor of the analyte that it is desired to detect and/or quantify. The requirement is that the binding partner concerned be capable of binding to the analyte being sought, preferably specifically. Thus, it is known practice to refer to the ELISA assay for assays which use binding partners that are not immunological in the strict sense, more widely known as “ligand binding assays”, whereas the term “immuno” is included in the title in extenso corresponding to the acronym ELISA. In the interest of clarity and uniformity, the term “immune” is used in the present application to denote any biological analysis using at least one binding partner suitable for binding to the analyte being sought and detecting and/or quantifying the latter, preferably specifically, even when said binding partner is not of immunological nature or origin in the strict sense.

The term “GDH binding partner” is intended to mean any molecule capable of binding to GDH. By way of example of a GDH binding partner, mention may be made of antibodies, antibody fragments, nanofitins, GDH receptors, aptamers, DARPins or any other molecule which is known to have an interaction with GDH.

The binding partner antibodies are, for example, either polyclonal antibodies or monoclonal antibodies.

The polyclonal antibodies can be obtained by immunization of an animal with the target GDH as immunogen, followed by recovery of the desired antibodies in purified form, by taking the serum of said animal, and separation of said antibodies from the other serum constituents, for example by affinity chromatography on a column to which is attached an antigen specifically recognized by the antibodies, in particular the immunogen, or by means of a protein A or G.

The monoclonal antibodies can be obtained by the hybridoma technique widely known to those skilled in the art. The monoclonal antibodies can also be recombinant antibodies obtained by genetic engineering, using techniques ell known to those skilled in the art.

By way of example of antibody fragments, mention may be made of Fab, Fab′, and F(ab′)2 fragments and also scFvs (single chain variable fragments) and dsFvs (double-stranded variable fragments). These functional fragments can in particular be obtained by genetic engineering.

Nanofitins (commercial name) are small proteins which, like antibodies, are capable of binding to a biological target, thus making it possible to detect it, to capture it or quite simply to target it within an organism.

Aptamers are oligonucleotides, generally RNA or DNA, identified in libraries containing up to 10¹⁵ different sequences, by means of an in vitro combinatorial selection method known as SELEX for “Systematic Evolution of Ligands by Exponential Enrichment” (Ellington A D and Szostak J W., 1990). Most aptamers are composed of RNA, owing to the capacity of RNA to adopt varied and complex structures, thereby making it possible to create at its surface cavities of varied geometries, making it possible to bind various ligands. These are biochemical tools of interest which can be used in biotechnological, diagnostic or therapeutic applications. Their selectivity and their ligand-binding properties are comparable to those of antibodies.

“DARPins” for Designed Ankyrin Repeat ProteINS (Boersma Y L and Plütckthun A, 2011) are another class of proteins which make it possible to mimic antibodies and to be able to bind to target proteins with high affinity and high selectivity. They derive from the family of ankyrin proteins, which are adapter proteins which enable the attachment of integral membrane proteins to the spectrin/actin network which constitutes the “backbone” of the cell plasma membrane. The structure of ankyrins is based on the repetition of a unit of approximately 33 amino acids and the same is true of DARPins. Each unit has a secondary structure of helix-turn-helix type. DARPins contain at least three, preferably four to five, repeat units and are obtained by screening combinatorial libraries.

The binding partners used may or may not be specific for GDH. They are termed specific when they are capable of binding exclusively or virtually exclusively to GDH. They are termed nonspecific when the GDH-binding selectivity is lower and they are then capable of binding to other ligands, such as other proteins or antibodies. According to one preferred embodiment, the specific binding partners are preferred.

The glutamate dehydrogenase that needs to be stabilized is any glutamate dehydrogenase from Clostridium of which it is desired to detect the presence, for example that of Clostridium difficile, of Clostridium botulimum or of Clostridium perfringens. It includes all the possible variants. Such proteins are known and their sequences are described for example in the Uniprot database (www.uniprot.org).

Thus, the GDH from Clostridium difficile (Uniprot accession no. P27346) is a protein of 421 amino acids, the reference amino acid sequence of which is the following SEQ ID No 1:

        10         20         30         40 MSGKDVNVFE MAQSQVKNAC DKLGMEPAVY ELLKEPMRVI         50         60         70         80 EVSIPVKMDD GSIKTFKGFR SQHNDAVGPT KGGIRFHQNV         90        100        110        120 SRDEVKALSI WMTFKCSVTG IPYGGGKGGI IVDPSTLSQG        130        140        150        160 ELERLSRGYI DGIYKLIGEK VDVPAPDVNT NGQIMSWMVD        170        180        190        200 EYNKLTGQSS IGVITGKPVE FGGSLGRTAA TGFGVAVTAR        210        220        230        240 EAAAKLGIDM KKAKIAVQGI GNVGSYTVLN CEKLGGTVVA        250        260        270        280 MAEWCKSEGS YAIYNENGLD GQAMLDYMKE HGNLLNFPGA        290        300        310        320 KRISLEEFWA SDVDIVIPAA LENSITKEVA ESIKAKLVCE        330        340        350        360 AANGPTTPEA DEVFAERGIV LTPDILTNAG GVTVSYFEWV        370        380        390        400 QNLYGYYWSE EEVEQKEEIA MVKAFESIWK IKEEYNVTMR        410        420 EAAYMHSIKK VAEAMKLRGW Y

And the variants of which are:

TABLE 1 Uniprot accession No. of the variants Strain Q18CS0 Clostridium difficile (strain 630) C9XIV3 Clostridium difficile (strain CD196) C9YHY9 Clostridium difficile (strain R20291) G6B2V9 Clostridium difficile 002-P50-2011 G6BHV4 Clostridium difficile 050-P50-2011 D5S4M2 Clostridium difficile NAP07 G6BQY2 Clostridium difficile 70-100-2010 D5Q9B1 Clostridium difficile NAP08

The GDH from Clostridium perfringens is a protein which does not yet have a reference sequence in the Uniprot base. The first protein given in the Uniprot base (Uniprot accession No. Q8XK85) is the protein of strain 13/type A, of 448 amino acids, the amino acid sequence of which is the following SEQ ID No 2:

        10         20         30         40 MEVKKYVDNL MEDLKKNNPG ESEFLAAAEE VLYSLVPVLE         50         60         70         80 ENPKYMEEGI LERIVEPERV IMFRVPWVDD AGNVRVNRGY         90        100        110        120 RVQFNSAIGP YKGGLRFHPS VNLSIIKFLG PEQIFKNSLT        130        140        150        160 TLPIGGGKGG SNFDPKGKSD REIMRFCQSF MSELYRHIGP        170        180        190        200 NTDVPAGDIG VGGREIGYMF GQYKKLKNSV DAGVLTGKGL        210        220        230        240 TYGGSLARKE ATGYGLVYFV DEMIRDNGQT IEGKTVVISG        250        260        270        280 SGNVAIYATE KVQELGGKVV ALSDSSGYVY DENGIDLEVV        290        300        310        320 KEIKEVKRGR ISEYVNYVKT AKFTEGFRGI WNVKCDIALP        330        340        350        360 CATQNEIDKS SAKTLIDNGV IAVGEGANMP STLEAQKLFV        370        380        390        400 DNKILFAPAK AANAGGVATS ALEMSQNSLR MSWTFEEVDA        410        420        430        440 KLKDIMKNIY YNSRNAASEY GHDGNLIVGA NIAGFKKVAD AMLDHGII

And the variants of which are:

TABLE 2 Uniprot accession No. of the variants Strain Q8XK85 Clostridium perfringens (strain 13/Type A) Q0SST9 Clostridium perfringens (strain SM101/Type A) Q0TQ84 Clostridium perfringens (strain ATCC 13124/NCTC 8237/Type A) B1R556 Clostridium perfringens B str. ATCC 3626 B1BJJ0 Clostridium perfringens C str. JGS1495 B1BWI0 Clostridium perfringens E str. JGS1987 B1RGN1 Clostridium perfringens CPE str. F4969 B1V119 Clostridium perfringens D str. JGS1721 B1RPY4 Clostridium perfringens NCTC 8239 H7CWP7 Clostridium perfringens F262 H1CRA8 Clostridium perfringens WAL-14572

The GDH from Clostridium botulimum is a protein which does not yet have a reference sequence in the Uniprot base. The first protein given in the Uniprot base (Uniprot accession No. A5I2T3) is the protein of strain Hall/type A (ATCC3502, NCTC 13319), of 421 amino acids, the amino acid sequence of which is the following SEQ ID No 3:

        10         20         30         40 MAKENLNPFE NAQKQVKTAC DKLGMEPAVY ELLKEPQRVI         50         60         70         80 EVSIPVKMDD GSVKVFKGYR SQHNDAVGPT KGGVRFHPNV         90        100        110        120 SLDEVKALSI WMTFKCSVTG IPYGGGKGGI IVDPKTLSKG        130        140        150        160 ELERLSRGYI DGIHKLIGEK VDVPAPDVNT NGQIMAWMVD        170        180        190        200 EYNKLVGRSA IGVITGKPVE FGGSLGRNAA TGFGVAVTAR        210        220        230        240 EAAAKLGIDM KKAKLAIQGI GNVGSHTVLN CEKLGGTVVA        250        260        270        280 LAEWCKEEGT YAIYNENGLD GKAMIEYVKE NGNLLGYPGA        290        300        310        320 KKISLDEFWA LNVDILIPAA LENAITHENA SSINAKLVCE        330        340        350        360 AANGPITPDA DAILKEKGIT VTPDILTNAG GVTVSYFEWV        370        380        390        400 QNLYGYYWTE AEVEAKEEEA MVKAFESIWA IKEEYSVTMR        410        420 EAAYMHSIKK VAGAMKLRGW Y

And the variants of which, of 421, 447 or 450 amino acids according to the strains, are:

TABLE 3 Uniprot accession No. of the variants Strain B1IM79 Clostridium botulinum (strain Okra/Type B1)421 B1KSB4 Clostridium botulinum (strain Loch Maree/Type A3) A7FUM1 Clostridium botulinum (strain ATCC 19397/Type A) E8ZRR3 Clostridium botulinum (strain H04402 065/Type A5) B2TLD1 Clostridium botulinum (strain Eklund 17B/Type B) C1FNV0 Clostridium botulinum (strain Kyoto/Type A2) B2V1W6 Clostridium botulinum (strain Alaska E43/Type E3) C3KX46 Clostridium botulinum (strain 657/Type Ba4) D5VZM8 Clostridium botulinum (strain 230613/Type F) F4A4K5 Clostridium botulinum BKT015925 A7GE56 Clostridium botulinum (strain Langeland/NCTC 10281/Type F) B1B9U1 Clostridium botulinum C str. Eklund C5VRL1 Clostridium botulinum D str. 1873 B1QDG7 Clostridium botulinum NCTC 2916 B1QQR1 Clostridium botulinum Bf M1ZQM8 Clostridium botulinum CFSAN001627 L1LK36 Clostridium botulinum CFSAN001628 C5UPY2 Clostridium botulinum E1 str. ‘BoNT E Beluga’

According to one particular embodiment, the glutamate dehydrogenase is an enzyme from the bacterium of the species Clostridium difficile.

The glutamate dehydrogenase placed in an aqueous solution is either of natural origin, or of recombinant origin. The natural, or otherwise termed native, glutamate dehydrogenase can be obtained after culturing the Clostridium bacterium and purifying the protein from the bacterial lysate. The recombinant glutamate dehydrogenase can be obtained by genetic engineering, using techniques well known to those skilled in the art. Such obtaining is described, for example, by Anderson B M et al., 1993. The recombinant glutamate dehydrogenase can be obtained from companies such as Holzel Diagnostika GmbH (Germany).

The term “aqueous composition or solution” is intended to mean a clear liquid solution obtained by complete dissolution of one or more compounds and the major solvent of which is water, representing at least 50% by volume, generally at least 60%, 70%, 80% or 90%, relative to the total volume of the solution.

In the context of the present invention, the aqueous composition or solution is obtained by diluting the GDH in a solvent comprising predominantly water and a stabilizing compound as defined hereinafter. The stabilizing compound to be added to the aqueous solution containing the GDH to be stabilized is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof.

The expression “carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups” is intended to mean a molecule consisting of:

-   -   a linear or branched carbon-based chain which is continuous         (i.e. without interruption in the carbon-based chain) or         interrupted with at least one other atom other than a carbon         atom, for example a nitrogen or oxygen atom,     -   at least two —COOH groups at the chain end and     -   at least one “CX” group, either at the chain end (it is then         written —CX), or in the middle of the chain (it is then written         —CX—), X being other than C.

For example, the —CX— groups are chosen independently from —CH₂—, ═CH—, —C(H)OH—, —C(H)NH₂— and —C(O)—. The —CX groups are for their part chosen independently from —CH₃, —COOH (if there are more than two —COOH groups in the molecule) and —C(O)NH₂.

Thus, for example, the stabilizing compound may be succinic acid, of formula OH(O)C—(CH₂)₂—C(O)OH, which is a molecule having a contiguous linear carbon-based chain of four carbon atoms, two —COOH groups at the chain end and two —CH₂— groups.

Another example consists of fumaric acid of formula OH(O)C—(CH═CH)—C(O)OH, which is a molecule having a contiguous linear carbon-based chain of four carbon atoms, two —COOH groups at the chain end and two —CH— groups.

Yet another example consists of N-(2-acetamido)iminodiacetic acid, of formula H₂NC(O)—CH₂—N(CH₂—COOH)₂, which is a molecule having a branched carbon-based chain of six carbon atoms, interrupted with a nitrogen atom, consisting of two —COOH groups at the chain end, of three —CH₂— groups and of one —C(O)NH₂ group.

According to one particular embodiment, the stabilizing compound is chosen from: fumaric acid, succinic acid, malic acid, glutaric acid, citric acid, tartaric acid, N-(2-acetamido)iminodiacetic acid, glutamic acid, adipic acid, aspartic acid, pimelic acid, malonic acid, and salts thereof, the formulae of which are given in FIG. 1.

The term “carboxylic acid salt” is intended to mean a salt of a monovalent cation. By way of monovalent cation, mention may be made of ammonium (NH4⁺), silver (Ag⁺), diamine silver (Ag(NH₃)₂ ⁺), cesium (Cs⁺), copper (I) (Cu⁺), mercury (Hg⁺), methanium (CH₅ ⁺), methylium (CH₃ ⁺) and nitrosium (NO₂ ⁺) ions and ions of the alkali metals sodium (Na⁺), potassium (K⁺) and lithium (Li⁺).

When the stabilizing compound is in salt form, at least one proton H⁺ of the —COOH groups is replaced with a monovalent cation described above.

According to one preferred embodiment, the stabilizing compound is chosen from succinic acid, fumaric acid, and salts thereof, in particular alkali metal salts, as defined above.

The carbon-based chain may comprise one or more of the following characteristics:

-   -   it may comprise at three carbon atoms to at most ten atoms,         preferably at most eight, preferably at most seven, preferably         at most six atoms,     -   it intercalates a nitrogen atom or it is contiguous and consists         only of carbon atoms,     -   the “CX” groups are chosen independently from —CH₂—, —CH—, —CH₃,         —COOH, —C(H)OH—, —C(O)NH₂, —C(H)NH₂— and —C(O)—, and     -   it may or may not comprise one or more double bonds and the acid         may then be in E or Z isomer form.

In particular, the carboxylic acid may have one or more of the following characteristics:

-   -   a carbon-based chain of 4, 5 or 6 carbon atoms,     -   a carbon-based chain of four carbon atoms having at least two         —COOH groups and —CX— chosen independently from ═CH—, —CH₂— and         —C(H)OH—,     -   a carbon-based chain of five carbon atoms having at least two         —COOH groups and —CX— groups chosen from —CH₂— and —C(H)NH₂ —,     -   a carbon-based chain of six carbon atoms having at least two         —COOH groups and “CX” groups chosen from—CH₂—, —C(H)OH— (—CX—)         and —C(O)NH₂ (—CX),     -   one double bond and is an E isomer,     -   two —COOH groups.

The amount of GDH present in the aqueous solution depends on the final use of the aqueous composition which contains it. In the context of a conventional immunoassay, the GDH may be present in a proportion of from 0.75 to 10 ng/ml, or from 2 to 10 ng/ml, preferably from 3 to 6 ng/ml. In the context of an “ultrasensitive” immunoassay, the GDH will be present in a much lower amount, for example less than one pg/ml, or even about one fg/ml.

The amount of stabilizing compound to be added to the aqueous solution containing the GDH is in large excess relative to the amount of GDH. It depends on whether the stabilizing compound is used only as a stabilizing compound, another molecule then being added as a buffer, or else whether it is used both as a stabilizing compound and as a buffer. Thus, for example, when the stabilizing compound is only used as a stabilizing compound, from 20 to 100 molecules of stabilizing compound are added per GDH monomer, preferably from 30 to 80 molecules of stabilizing compound per GDH monomer, more preferably from 40 to 60 molecules of stabilizing compound per GDH monomer. In this case, the compound added as a buffer is any compound known to those skilled in the art having a pH of between 4.5 and 7, preferably between 5.5 and 6.5, a pH of 5.8 being preferred. By way of example of a compound added as a buffer, mention may be made of phosphate and acetate. When the stabilizing compound is used both as a stabilizing compound and as a buffer, from 10⁸ to 10¹⁰ molecules of stabilizing compound are added per GDH monomer, preferably from 1×10⁹ to 5×10⁹ molecules of stabilizing compound per GDH monomer, more preferably from 1×10⁹ to 2×10⁹ molecules of stabilizing compound per GDH monomer.

Other compounds may also be added to the aqueous composition in the process of the invention. Thus, for example, a polyol may be added. The addition of polyol makes it possible to promote the heat stability of the proteins (resistance to heat denaturation) and also to prevent aggregation. Generally, polyols have a co-solvent effect and contribute to maintaining the native conformation of proteins in an aqueous solution.

By way of examples of polyol, mention may be made of monosaccharide polyols such as triols, for example glycerol, tetraols, for example erythritol, pentols, for example xylitol, arabitol and ribitol, hexols, for example sorbitol, dulcitol and mannitol, heptols, for example volemitol, and also disaccharide polyols such as maltitol, isomaltitol and lactitol.

According to one embodiment of the invention, the polyol added to the aqueous composition of the process of the invention is sorbitol.

The polyol is added to the aqueous composition in a proportion of at least 1%, preferably at least 5% and more preferably at least 10%, with at most 50%.

The composition may also comprise another macro molecule, generically referred to as a “filler protein” even though macromolecules other than proteins are appropriate, which has nothing to do with the GDH, but is present in large excess relative to the GDH, further improving the stabilization of the GDH. This “filler protein” has a shield effect in the sense that it will partially undergo physicochemical modifications in the aqueous solution, thus making it possible to protect the molecule of interest, in this case GDH. This added macromolecule may for example be a protein such as BSA (bovine serum albumin), or else synthetic polymers of dextran or polyethylene glycol type. BSA, for example, is added in a proportion of 50 g/l compared with 3 mg/l of GDH.

The aqueous composition is buffered so as to have a pH of between 4.5 and 7, preferably between 5.5 and 6.5, a pH of 5.8 being preferred. As previously indicated, the stabilizing compound of the invention may also be used as a buffer, or else another buffer compound may be added.

The aqueous compositions comprising the glutamate dehydrogenase from a bacterium of the Clostridium genus and a stabilizing compound which is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof, it being understood that the stabilizing compound is neither glutamate, nor alpha-ketoglutarate, produced from hydrolysis of the glutamate by the GDH enzyme and the NAD+ coenzyme, nor citrate, nor succinate, nor glutarate, are novel and constitute another subject of the invention.

According to another embodiment, the aqueous compositions of the invention also exclude glutamic acid, alpha-ketoglutaric acid, glutaric acid, succinic acid and/or citric acid.

When the bacterium of the Clostridium genus is chosen from the species Clostridium difficile, Clostridium botulinum and Clostridium perfringens, then the aqueous compositions comprising the glutamate dehydrogenase from one of these bacteria and a stabilizing compound which is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof, it being understood that the stabilizing compound is neither glutamate, nor alpha-ketoglutarate, nor citrate, are novel and constitute another subject of the invention.

According to another embodiment, the aqueous compositions of the invention also exclude glutamic acid, alpha-ketoglutaric acid and/or citric acid.

The same characteristics and preferences described previously, in particular with regard to the choice of the GDH, of the stabilizing compound, of the compounds to be added and of the relative amount thereof, given in relation to the process, also apply to the aqueous compositions according to the invention.

The aqueous compositions of the invention, in particular those obtained according to the process of the invention, are particularly useful for detecting the presence of a bacterium of the Clostridium genus in a biological sample that may contain such a bacterium. Thus, the kits containing such compositions constitute another subject of the invention.

The biological samples that may contain a bacterium of the Clostridium genus may be samples from the clinical field or from the field of testing innocuity, or even sterility of industrial products. In the clinical field, the sample is an animal, preferably human, biological specimen, such as stools or derivatives, for example an extract of fecal proteins, urine, blood or derivatives, for example serum or plasma, pus, etc. In the industrial field, the sample comes from a food or cosmetic product.

The kits according to the invention may also contain the compounds required for carrying out a process for detecting, for example by immunoassay, the presence of a bacterium of the Clostridium genus, and in particular Clostridium difficile. Thus, for example, the kits may contain one or more GDH-binding partners as previously described, and all the compounds required for demonstrating the reaction between the binding partner(s) and the GDH.

The qualitative or quantitative GDH immunological assay will preferably be a sandwich assay, which is an assay widely known to those skilled in the art using two GDH-binding partners. One of the two partners may be coupled to a label so as to form a conjugate or a tracer. The other binding partner may be captured on a solid support. The term “capture partner” is then used for the latter and detection partner is then used for the former.

The measured signal emitted by the conjugate is then proportional to the amount of GDH in the biological sample.

The term “label” is intended to mean in particular any molecule containing a group that reacts with a group of the binding partner, directly without chemical modification, or after chemical modification so as to include such a group, which molecule is capable of directly or indirectly generating a detectable signal. A nonlimiting list of these direct detection labels consists of:

-   -   enzymes which produce a detectable signal for example by         colorimetry, fluorescence, luminescence, such as horseradish         peroxydase, alkaline phosphatase, β-galactosidase or         glucose-6-phosphate dehydrogenase,     -   chromophores such as fluorescent, luminescent or dye compounds,     -   radioactive molecules such as ³²P, ³⁵S or ¹²⁵I,     -   fluorescent molecules such as Alexas or phycocyanins, and     -   electrochemiluminescent salts such as organometallic derivatives         based on acridinium or on ruthenium.

Indirect detection systems may also be used, for instance ligands capable of reacting with an anti-ligand. The ligand then corresponds to the label so as to constitute, with the binding partner, the conjugate.

Ligand/anti-ligand pairs are well known to those skilled in the art, which is the case, for example, of the following pairs: biotin/streptavidin, hapten/antibody, antigen/antibody, peptide/antibody, sugar/lectin, polynucleotide/polynucleotide complementary to said polynucleotide.

The anti-ligand may then be directly detectable by the direct detection labels previously described or be itself detectable by another ligand/anti-ligand pair, and so on.

These indirect detection systems may result, under certain conditions, in an amplification of the signal. This signal amplification technique is well known to those skilled in the art, and reference may be made to the applicant's prior patent applications FR 2781802 or WO 95/08000.

Depending on the type of labeling used, those skilled in the art will add reagents which allow the visualization of the labeling or the emission of a signal detectable by any type of appropriate measuring apparatus, for instance a spectrophotometer, a spectrofluorimeter, a densitometer or else a high-definition camera.

In the GDH assay processes, aqueous compositions of the invention, where appropriate obtained according to the process of the invention, are particularly useful for establishing a standard range, this constituting another subject of the invention. The establishing of the standard range, a step that is necessary in order to be able to quantify the GDH, is a step widely known to those skilled in the art. Briefly, it consists in measuring the signal generated by increasing and known amounts or concentrations of the GDH analyte, in plotting the curve giving the signal as a function of the amount or the concentration and in finding a mathematical model which represents this relationship in the most faithful way possible. To do this, several aqueous compositions of the invention are used, each containing a different GDH concentration. The mathematical model will be used to determine by extrapolation the unknown amounts or concentrations of GDH contained in the biological sample to be tested.

The aqueous compositions of the invention, where appropriate obtained according to the process of the invention, are also particularly useful as a calibrator, which constitutes another subject of the invention. In this case, the GDH concentration of the composition is fixed and known. The signal generated during the use of the immunoassay kit by the calibrator is also known. The calibrator is used to verify that the measurement (signal) produced during the use of the immunoassay kit indeed corresponds to the expected value. If this is not the case, the calibrator is used to measure the shift which may, where appropriate, be corrected mathematically or by a physical intervention on the measuring instrument (adjustment).

The aqueous compositions of the invention, where appropriate obtained according to the process of the invention, are also particularly useful as a control, which constitutes another subject of the invention. In this respect, they are used, for example, to verify that the immunoassay kit operates according to expectations (also called positive control) and that the detection of the GDH in the biological sample is not falsely negative in so far as the detection method has operated correctly with the aqueous composition of the invention.

The detection of GDH in a biological sample makes it possible to conclude that the bacterium is present.

Thus, another subject of the invention relates to a process for detecting the presence of a bacterium of the Clostridium genus in a biological sample that may contain such a bacterium, characterized in that it comprises the steps of (i) carrying out a process for detecting the presence of a bacterium of the Clostridium genus by detecting or quantifying glutamate dehydrogenase in said sample using an aqueous composition of the invention, where appropriate as obtained according to the process of the invention, or else a kit as previously defined, and

(ii) if the process of step (i) is positive, concluding that the bacterium is present.

In other words, for step (ii), a positive result in step (i) makes it possible to conclude that the bacterium is present.

On the other hand, this provides no information as to whether or not this bacterium produces at least one toxin, which is particularly important as an aid to diagnosis when a patient presents symptoms that might be caused by the presence of a bacterium which is toxigenic and which expresses at least one toxin.

Thus, another subject of the invention relates to a process for detecting the presence of a toxigenic bacterium of the Clostridium genus which produces at least one toxin, in a biological sample that may contain such a bacterium and at least one such toxin, characterized in that it comprises the steps of:

(i) carrying out a process for detecting the presence of a bacterium of the Clostridium genus by detecting or quantifying glutamate dehydrogenase in said sample using an aqueous composition of the invention, where appropriate as obtained according to the process of the invention, or else a kit as previously defined, and (ii) if the process of step (i) is negative, concluding that the bacterium is absent, or (ii′) if the process of step (i) is positive, carrying out a process for detecting or quantifying at least one toxin that may be released by said bacterium of the Clostridium genus, in the same biological sample, or in a new biological sample from the same individual, and concluding that the bacterium is toxigenic and produces said at least one toxin if said at least one toxin is present.

In other words, for step (ii), a negative result in step (i) makes it possible to conclude that the bacterium is absent and a positive result in step (i) makes it possible to conclude that the bacterium is present.

Step (i) above consisting in detecting the presence of a bacterium of the Clostridium genus by detecting or quantifying glutamate dehydrogenase in the biological sample has been described previously. The aqueous composition of the invention, where appropriate obtained by means of the process of the invention, can then be used to produce the standard range and/or as a calibrator and/or as a positive control.

Step (ii′) above consisting in detecting or quantifying at least one toxin that may be released by said bacterium of the Clostridium genus is a step widely known to those skilled in the art. Such detecting or quantifying may be carried out, for example, by immunoassay using partners for binding to the toxins being sought. The toxin immunoassay is carried out in a manner similar to the GDH immunoassay as described previously. Kits for immunoassaying toxin from bacteria of the Clostridium genus are commercially available, for instance the VIDAS® Clostridium difficile A&B kit which makes it possible to detect Clostridium difficile toxins A and B.

Mass spectrometry may also be used to carry out the step of detecting/quantifying the toxin. This technique is an analytical technique which makes it possible to determine the molar mass of the compounds analyzed, and also to identify their molecular structure, or even to quantify them. Applied to a complex mixture such as a biological fluid or stools, it needs to be coupled to a separative technique which makes it possible to reduce the complexity thereof. This is usually gas chromatography (GC) or liquid chromatography (LC). Tandem mass spectrometry (MS/MS) combines two analyzers and may be used for the purposes of detection/quantification. The ionic compounds selected in the first analyzer and then fragmented are analyzed more finely in the second. This double analysis makes it possible to significantly increase the specificity of the method. For this technology, reference may in particular be made to Van den Broek et al., 2013.

The detecting and/or quantifying of the toxins may also be carried out by means of a test for immunotoxicity in the stools (CTA) which makes it possible to demonstrate the biological effects of toxins in the stools (Eckert C. et al., 2011).

The detecting or quantifying of the toxin is carried out in the same biological sample as that used for detecting or quantifying the GDH, a part of which has been kept in this respect, or else in a new biological sample from the same origin, i.e. from the individual from whom the first biological sample tested with respect to the presence of GDH came if the biological sample is a clinical sample or from the same source if the biological sample is an industrial sample. The second biological sample is either of the same nature, or of different nature, the first case being preferred.

According to one particular embodiment, the toxigenic bacterium of which it is desired to detect the presence is Clostridium difficile and said at least one toxin comprises toxin A, toxin B or both.

Other toxigenic bacteria of the Clostridium genus have been described previously.

The invention will be understood more clearly by means of the following examples which are given by way of nonlimiting illustration, and also by means of FIGS. 1 and 2, in which:

FIG. 1 gives examples of stabilizing compounds used in the aqueous compositions according to the invention, and also the chemical formula thereof, and

FIG. 2 is a graph giving the change in the fluorescent signal obtained during an immunoassay with the VIDAS® GDH kit (bioMérieux) emitted by aqueous compositions according to the invention or comparative compositions, as a function of time, when these compositions are maintained at 37° C.

EXAMPLES Example 1 Preparation of Recombinant GDH from Clostridium difficile

The gluD gene encoding the GDH from Clostridium difficile (Genbank accession No. M65250), with a sequencing encoding a HIS tag added thereto, is cloned into the pMR78 vector (bioMérieux, France). The expression plasmid thus constructed is introduced into E. coli BL21 bacteria and derivatives (Stratagene, Agilent Technologies). The cultures are carried out in 2× YT medium (Difco), in the presence of ampicillin, at 37° C. with shaking. The expression of the protein is induced by adding 1 mM of IPTG (isopropyl beta-D-1-thiogalactopyranoside). The bacteria are collected by centrifugation at the end of culturing.

The bacterial pellets are taken up in 2× PBS buffer (phosphate buffered saline) and lysed. The lysates are centrifuged at 3000 g for 30 min at 4° C. The supernatant contains the soluble proteins, including the recombinant GDH to be purified.

The purification of the protein is carried out by one-step metal chelate affinity chromatography. The supernatant obtained after centrifugation is loaded onto an Ni-NTA-Agarose resin (Qiagen). After a washing cycle, the protein is eluted in the presence of an imidazol gradient. The protein is dialyzed in a 20 mM phosphate buffer.

Example 2 Demonstration of the Stabilization of the Antigenic Properties of GDH Using Stabilizing Compounds According to the Invention

The recombinant GDH, prepared in example 1, is diluted to 3 ng/ml in the following formulations, according to the indications relating to the calibrator and control (S1/C1) given in the information sheet for the VIDAS® GDH reagent (Ref 30125, bioMérieux, France):

-   -   Comparative composition: 100 mM phosphate+50 g/l BSA, pH 5.8         (formulation of the calibration solution of the Vidas® kit, GDH         in lyophilized form, taken up in demineralized water),     -   Composition according to the invention 1: 100 mM         N-(2-acetamido)iminodiacetic acid (ADA)+50 g/l BSA, pH 5.8 (ADA         composition),     -   Composition according to the invention 2: 100 mM succinic         acid+50 g/l BSA, pH 5.8 (succinate composition),     -   Composition according to the invention 3: 100 mM disodium         fumarate+50 g/l BSA, pH 5.8 (fumarate composition),

Each composition (comparative and ADA, succinate and fumarate) was prepared beforehand as follows: each stabilizing compound (1.18 g of succinic acid—Merck, 1.6 g of dibasic sodium fumarate—Sigma, 1.90 g of ADA—Sigma or 0.78 g of phosphate NaH₂PO₄.2H₂O+1.79 g of Na₂HPO₄.12H₂O) was mixed with demineralized water so as to obtain 50 ml. 10N NaOH was then added so as to adjust the pH to 5.8. Five g of BSA (Millipore) were added. Finally, demineralized water was added to as to obtain a solution of 100 ml.

The four compositions containing the GDH are then aliquoted into fractions of 1 ml and then stored at 37+/−1° C. The impact of the formulation on the stability of the antigenic properties of the recombinant GDH protein is evaluated by carrying out several GDH assays over a period of 91 days with the VIDAS® GDH kit (Ref 30125) and the VIDAS® instrument according to the instructions of the manufacturer (bioMérieux, France).

The implementation of the VIDAS GDH test adheres to the protocol of the kit sold:

-   -   introduction of 200 μl of sample+1 ml of the RI pretreatment         reagent     -   homogenization by vortexing     -   introduction of 300 μl of this dilution to 1/6 into the sample         well of the cartridge of the VIDAS® GDH kit.

Each aliquot is used for only one monitoring timepoint, but is systematically used in duplicate. The VIDAS instrument measures a fluorescence signal and the results are expressed as “relative fluorescence value” or RFV.

The RFV results obtained for the two measurements in duplicate (1 and 2) and also the D/D0 ratio (RFV on day D relative to RFV on day 0) are given in table 4 below and are also reproduced on the graph of FIG. 2.

TABLE 4 Comparative ADA Succinate Fumarate Days composition composition composition composition 37° C. 1 2 D/D0 1 2 D/D0 1 2 D/D0 1 2 D/D0 0 417 445 1 428 451 1 419 462 1 446 428 1 7 132 137 0.31 355 357 0.81 339 371 0.81 371 364 0.84 14 25 25 0.06 278 311 0.67 343 340 0.78 375 378 0.86 28 8 12 0.02 249 221 0.53 336 354 0.78 329 329 0.75 63 NA NA NA 124 108 0.26 258 260 0.59 322 302 0.71 91 NA NA NA 59 64 0.14 209 210 0.48 297 302 0.69 NA = not applicable

The results demonstrate that, at 37° C., the use of stabilizing compounds consisting of carboxylic acids having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups makes it possible to very substantially improve the storage time of an aqueous solution containing GDH since, for the comparative composition, there is no longer any signal at 28 days, whereas the D/D0 ratio at this date for the compositions according to the invention is at least equal to 0.5.

Example 3 Monitoring of the Antigenic Properties of GDH in an Aqueous Solution Using Citric Acid as Stabilizing Compound

The procedure of example 2 was repeated, except for the fact that citric acid (100 mM) was used as stabilizing compound and that the aqueous solutions were stored for a longer period of time, at 2-8° C. and at 37° C.

The RFV results obtained for the two measurements in duplicate (1 and 2) and also the D/D0 ratio are given in table 5 below.

TABLE 5 Citrate composition - Citrate composition - 37° C. 2-8° C. Days 1 2 D/D0 1 2 D/D0 0 713 677 1 713 677 1 1 697 757 1.05 653 722 0.99 7 717 683 1 636 694 0.96 14 666 678 0.97 646 700 0.97 29 521 565 0.78 692 680 0.99 51 421 418 0.6 613 641 0.9 78 233 222 0.33 701 680 0.99 124 67 67 0.1 648 690 0.96 184 6 10 0.01 739 774 1.09 275 NA NA NA 657 663 0.95 369 NA NA NA 664 612 0.92 552 NA NA NA 523 558 0.78 NA: not applicable

The above results demonstrate that the addition of citric acid allows very good stability associated with the preservation of the antigenic properties of the GDH, with a virtually optimal stabilization, even after 18 months, when the aqueous composition is stored between 2-8° C.

Example 4 Monitoring of the Antigenic Properties of GDH in an Aqueous Solution Using Succinic Acid and Sorbitol

The procedure of example 2 was repeated, except for the fact that 10% of sorbitol was also added to a succinate composition and that the aqueous solutions were stored for a longer period of time, at 2-8° C. and at 37° C.

The RFV results obtained for the two measurements in duplicate (1 and 2) and also the D/D0 ratio are given in table 6 below.

TABLE 6 Succinate composition Succinate composition with with sorbitol - 37° C. sorbitol - 2-8° C. Days 1 2 D/D0 1 2 D/D0 0 726 710 1 726 710 1 1 740 714 1 744 700 1.01 7 702 696 0.97 725 764 1.04 14 689 655 0.94 720 765 1.03 29 624 658 0.89 690 708 0.97 51 653 646 0.9 603 668 0.89 78 606 591 0.83 670 720 0.97 124 529 556 0.76 709 691 0.97 184 379 376 0.53 656 785 1 275 267 286 0.39 659 710 0.95 369 156 161 0.22 692 663 0.94 552 48 48 0.07 663 710 0.96 891 NC NC NC 638 681 0.92 NC: not calculated

The above results demonstrate that succinic acid also allows a lengthy stabilization of the antigenic properties of the GDH in an aqueous solution, the addition of sorbitol not modifying this stabilization, with a stabilization which is virtually optimal, even after approximately 30 months, when the aqueous solution is stored between 2-8° C.

LITERATURE REFERENCES

-   -   Anderson B M et al, 1993, Archives of Biochemistry and         Biophysics, 300(1): 483-488     -   Boersma Y L, Plückthun A, 2011, Curr. Opin. Biotechnol, 22:         849-857     -   Eckert C. et al., 2011, Journal des Anti-Infectieux, 13(2):         109-116     -   Ellington A D et Szostak J W., 1990, Nature, 346: 818-822     -   Garcia-Galan C. et al., 2013, Enzyme and Microbial Technology,         52(4-5): 211-217     -   Van den Broek et al., 2013, J. Chromatogr. B, 929: 161-179 

The invention claimed is:
 1. A process for stabilizing glutamate dehydrogenase from a bacterium of the Clostridium genus in order to maintain antigenic properties of the glutamate dehydrogenase, comprising: stabilizing the glutamate dehydrogenase in an aqueous solution comprising (i) the glutamate dehydrogenase in a concentration ranging from 0.75 to 10 ng/ml, (ii) a stabilizing compound that is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof, (iii) any of a monosaccharide polyol, disaccharide polyol, or polymeric macromolecule in addition to the glutamate dehydrogenase, and (iv) a buffer; and maintaining the antigenic properties of the glutamate dehydrogenase during storage of the aqueous solution, wherein: the aqueous solution has a pH of between 4.5 and 7; and the aqueous solution comprises 20 to 100 molecules of the stabilizing compound per glutamate dehydrogenase monomer.
 2. The process as claimed in claim 1, wherein the carboxylic acid contains a carbon-based chain of 4, 5 or 6 carbon atoms.
 3. The process as claimed in claim 1, wherein the stabilizing compound is chosen from the following carboxylic acids and salts thereof: (i) carboxylic acids containing a carbon-based chain of four carbon atoms having at least two —COOH groups and —CX— groups chosen independently from ═CH—, —CH₂— and —C(H)OH—, and (ii) carboxylic acids containing a carbon-based chain of five carbon atoms having at least two —COOH groups and —CX— groups chosen from —CH₂— and —C(H)NH₂—, and (iii) carboxylic acids containing a carbon-based chain of six carbon atoms having at least two —COOH groups and “CX” groups chosen from —CH₂—, —C(H)OH—and —C(O)NH₂.
 4. The process as claimed in claim 1, wherein the carboxylic acid contains a double bond in its carbon-based chain and is an E isomer.
 5. The process as claimed in claim 1, wherein the carboxylic acid contains two —COOH groups.
 6. The process as claimed in claim 1, wherein the stabilizing compound is chosen from fumaric acid, succinic acid, malic acid, glutaric acid, citric acid, tartaric acid, N-(2-acetamido)iminodiacetic acid, glutamic acid, adipic acid, aspartic acid, pimelic acid and malonic acid, and salts thereof.
 7. The process as claimed in claim 1, wherein the stabilizing compound is chosen from succinic acid and fumaric acid, and salts thereof.
 8. The process as claimed in claim 1, wherein the stabilizing compound is chosen from malic acid, glutaric acid, citric acid, N-(2-acetamido)iminodiacetic acid, glutamic acid, adipic acid, pimelic acid and malonic acid, and salts thereof.
 9. The process as claimed in claim 1, wherein the buffer is a phosphate or acetate buffer.
 10. The process as claimed in claim 1, wherein the aqueous solution comprises any of glycerol, erythritol, xylitol, arabitol, ribitol, sorbitol, dulcitol, mannitol, or volemitol as the monosaccharide polyol.
 11. The process as claimed in claim 1, wherein the aqueous solution comprises any of maltitol, isomaltitol, or lactitol as the disaccharide polyol.
 12. The process as claimed in claim 1, wherein the aqueous solution comprises a filler protein as the polymeric macromolecule.
 13. The process as claimed in claim 1, wherein the aqueous solution comprises a dextran or polyethylene glycol polymer as the polymeric macromolecule.
 14. The process as claimed in claim 1, further comprising binding a binding partner to the glutamate dehydrogenase to detect or quantify the glutamate dehydrogenase as part of a glutamate dehydrogenase immunoassay.
 15. The process as claimed in claim 14, wherein the glutamate dehydrogenase is detected or quantified as a control, calibrator, or for establishing a standard concentration range.
 16. An aqueous composition comprising: (i) glutamate dehydrogenase from a bacterium of the Clostridium genus in a concentration ranging from 0.75 to 10 ng/ml; (ii) a stabilizing compound that is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof; (iii) any of a monosaccharide polyol, disaccharide polyol, or polymeric macromolecule in addition to the glutamate dehydrogenase; and (iv) a buffer, wherein: the aqueous composition has a pH of between 4.5 and 7; and the aqueous composition comprises 20 to 100 molecules of the stabilizing compound per glutamate dehydrogenase monomer.
 17. A kit for detecting the presence of a bacterium of the Clostridium genus in a biological sample that may contain the bacterium, comprising the aqueous composition as claimed in claim 16 and compounds required for carrying out a process for detecting the presence of the bacterium of the Clostridium genus.
 18. A process for stabilizing glutamate dehydrogenase from a bacterium of the Clostridium genus in order to maintain antigenic properties of the glutamate dehydrogenase, comprising: stabilizing the glutamate dehydrogenase in an aqueous solution comprising (i) the glutamate dehydrogenase in a concentration ranging from 0.75 to 10 ng/ml, (ii) a stabilizing compound that is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof, and (iii) any of a monosaccharide polyol, disaccharide polyol, or polymeric macromolecule in addition to the glutamate dehydrogenase; and maintaining the antigenic properties of the glutamate dehydrogenase during storage of the aqueous solution, wherein: the aqueous solution has a pH of between 4.5 and 7; and the aqueous solution comprises 10⁸ to 10¹⁰ molecules of the stabilizing compound per glutamate dehydrogenase monomer.
 19. The process as claimed in claim 18, wherein the carboxylic acid contains a carbon-based chain of 4, 5 or 6 carbon atoms.
 20. The process as claimed in claim 18, wherein the stabilizing compound is chosen from the following carboxylic acids and salts thereof: (i) carboxylic acids containing a carbon-based chain of four carbon atoms having at least two —COOH groups and —CX— groups chosen independently from ═CH—, —CH₂— and —C(H)OH—, and (ii) carboxylic acids containing a carbon-based chain of five carbon atoms having at least two —COOH groups and —CX— groups chosen from —CH₂— and —C(H)NH₂—, and (iii) carboxylic acids containing a carbon-based chain of six carbon atoms having at least two —COOH groups and “CX” groups chosen from —CH₂—, —C(H)OH— and —C(O)NH₂.
 21. The process as claimed in claim 18, wherein the carboxylic acid contains a double bond in its carbon-based chain and is an E isomer.
 22. The process as claimed in claim 18, wherein the carboxylic acid contains two —COOH groups.
 23. The process as claimed in claim 18, wherein the stabilizing compound is chosen from fumaric acid, succinic acid, malic acid, glutaric acid, citric acid, tartaric acid, N-(2-acetamido)iminodiacetic acid, glutamic acid, adipic acid, aspartic acid, pimelic acid and malonic acid, and salts thereof.
 24. The process as claimed in claim 18, wherein the stabilizing compound is chosen from succinic acid and fumaric acid, and salts thereof.
 25. The process as claimed in claim 18, wherein the stabilizing compound is chosen from malic acid, glutaric acid, citric acid, N-(2-acetamido)iminodiacetic acid, glutamic acid, adipic acid, pimelic acid and malonic acid, and salts thereof.
 26. The process as claimed in claim 18, wherein the aqueous solution comprises at least 50% by volume of water.
 27. The process as claimed in claim 18, wherein the aqueous solution comprises any of glycerol, erythritol, xylitol, arabitol, ribitol, sorbitol, dulcitol, mannitol, or volemitol as the monosaccharide polyol.
 28. The process as claimed in claim 18, wherein the aqueous solution comprises any of maltitol, isomaltitol, or lactitol as the disaccharide polyol.
 29. The process as claimed in claim 18, wherein the aqueous solution comprises a filler protein as the polymeric macromolecule.
 30. The process as claimed in claim 18, wherein the aqueous solution comprises a dextran or polyethylene glycol polymer as the polymeric macromolecule.
 31. The process as claimed in claim 18, further comprising binding a binding partner to the glutamate dehydrogenase to detect or quantify the glutamate dehydrogenase as part of a glutamate dehydrogenase immunoassay.
 32. The process as claimed in claim 31, wherein the glutamate dehydrogenase is detected or quantified as a control, calibrator, or for establishing a standard concentration range.
 33. An aqueous composition comprising: (i) glutamate dehydrogenase from a bacterium of the Clostridium genus in a concentration ranging from 0.75 to 10 ng/ml; (ii) a stabilizing compound that is a carboxylic acid having a carbon-based chain of at least three carbon atoms and comprising at least two —COOH groups, or a salt thereof; and (iii) any of a monosaccharide polyol, disaccharide polyol, or polymeric macromolecule in addition to the glutamate dehydrogenase; and the aqueous composition has a pH of between 4.5 and 7; and the aqueous composition comprises 10⁸ to 10¹⁰ molecules of the stabilizing compound per glutamate dehydrogenase monomer.
 34. A kit for detecting the presence of a bacterium of the Clostridium genus in a biological sample that may contain the bacterium, comprising the aqueous composition as claimed in claim 33 and compounds required for carrying out a process for detecting the presence of the bacterium of the Clostridium genus. 